201017323 六、發明說明: 【發明所屬的技術領域】 本發明是有關一種驅動單眼相機(SingleUnsRe版,簡 稱SLR)鏡頭伸、縮(Lens Zooming)的裝置,且特別是有關 -種於單眼相機的機身外,以坐式驅動單眼相機鏡頭伸縮的 裝置。 【先前技術】 一般消費型相機(Consumer Camera或稱Compact201017323 VI. Description of the Invention: [Technical Field] The present invention relates to a device for driving a single-lens camera (SingleUnsRe version, SLR for short) Lens Zooming, and in particular to a single-eye camera Outside, a device that telescopically drives a single-lens camera lens to telescope. [Prior Art] General Consumer Camera (Consumer Camera or Compact)
Camera)的鏡頭伸縮,都是以相機内的齒輪組及螺桿等來驅 動。但單眼相機的鏡頭,都是以手握鏡頭旋轉來達成鏡頭伸 縮的目的’並未有能控制鏡頭自動伸縮的功能。 部份相機製造商提供軟體開發組件(S〇ftwareCamera's lens expansion and contraction are driven by gear sets and screws in the camera. However, the lenses of the monocular camera are all held by the lens to achieve the lens expansion. There is no function to control the automatic telescopic expansion of the lens. Some camera manufacturers offer software development components (S〇ftware
Development Kits,簡稱SDK )來控制相機的預覽 (Preview )、拍照(Snap )、光圈(Aperture )、快門(Shutter )、 ISO感光度、白平衡(White Balance)等。但所提供的SDK 只能控制消費型相機鏡頭的自動伸縮,使得拍照全自動化得 以實現,然而卻沒有SDK能控制逐漸普及的單眼相機鏡頭自 動伸縮,致使單眼相機拍照全自動化獨缺鏡頭伸縮的控制。 同時,一般人想到自動驅動單眼相機鏡頭伸縮時,多數會 採用直接驅動鏡頭旋轉的方式,例如:於鏡頭上鎖定一齒輪, 並以馬達帶動的另一齒輪直接驅動鎖在鏡頭上的齒輪轉動。 然而,以上述方式直接驅動鏡頭旋轉會造成鏡頭歪斜及齒輪 咬合不完全的問題。所以,本發明將鎖在鏡頭上的套環 (Adapting Ring)坐靠及固定在一大齒輪(Big Gear)上, 4 201017323 【發明内容】 本發明目的之-為提供—_坐式驅動裝置來自動控 單眼相機鏡頭的伸縮,使得單眼相機能全自動由軟體開發植 件來控制。使用者不必接觸單眼相機即能由控制面板Development Kits (SDK for short) to control the camera's preview, Snap, Aperture, Shutter, ISO sensitivity, White Balance, and more. However, the provided SDK can only control the automatic expansion and contraction of the consumer camera lens, so that the camera can be fully automated. However, the SDK can control the gradually popularized monocular camera lens to automatically expand and contract, resulting in the monocular camera taking full automation and lacking the lens telescopic control. . At the same time, when people think of automatic driving of a single-lens camera lens, most of them will use the method of directly driving the lens to rotate. For example, a gear is locked on the lens, and another gear driven by the motor directly drives the gear locked on the lens to rotate. However, directly driving the lens rotation in the above manner causes the lens to be skewed and the gear to be incompletely engaged. Therefore, the present invention sits and fixes an Adapting Ring locked on the lens on a Big Gear, 4 201017323 [Invention] The object of the present invention is to provide a _ seated drive device. The telescopic expansion of the monocular camera lens allows the monocular camera to be fully automated and controlled by software development. The user can access the control panel without having to touch the monocular camera
(c〇ntr〇1 Panel)或電腦螢幕來操控單眼相機進行拍昭,所 有单眼相機的主要魏都能—覽無遺,並可促成單眼相 泛地被使用在全自動拍攝系統中。 為達成上述目的,本發明提供一種以坐式驅動單眼 頭伸縮的裝置,包括:-底盤(chassis)、—套環、—大窗 輪、一小齒輪以及-馬達。套環套在—單眼相機的—鏡頭上, 並坐靠及固定於大齒輪上。小齒輪用以帶動大齒輪轉動。馬 ,用以帶動小齒輪轉動。底盤用以承載核置的其 件及固定單眼相機。 關冬 為讓本發明的上述特徵和優點能更明顯易懂,下文特 個實施例’魏合所附圖式,作詳細說明如下。 【實施方式] 第1圖所不為依據本發明一實施例的以坐式驅動單眼相 機鏡頭伸縮的裝置的組立圖的正視圖(Fr〇ntview),說明組 成本發明裝置駐要零件以套環6及22 f束在單眼相機4 的鏡頭5上。套環6及22上並有定位孔(L〇ckH〇ie)仙及 41’ ^夺整個套環6及22坐靠在大齒輪14上,而大齒輪14 上的定位銷(Lock Pin) 1〇及44分別插入套環6及22上的 5 201017323 定位孔40及41内。小齒輪15由馬達18帶動旋轉’而大齒 輪14則由小齒輪15帶動旋轉,再由坐靠在大齒輪14上的套 環6及22轉動單眼相機4的鏡頭5,以達成驅動鏡頭5伸縮 的目的。以上所述乃為構成本發明裝置的主要零件,且上述 零件都置放在底盤42上。另外’再由底盤42下方往上鎖入 迴轉基座(Rotating Base) 9,而由迴轉基座9向上伸出的環 狀軸(Ring Shaft) 45則可作為大齒輪14的旋轉轴。於此實 施例中’大齒輪14與環狀轴45間更可嵌入無給油式襯套 (Oilless Bush) 11,且大齒輪14上方可透過一固定在固定 © 塊(Fixing Block) 7上的軸承(Bearing) 8導引大齒輪14 的盤面轉動。大齒輪14與迴轉基座9的水平接觸面之間,更 可置入平面針狀軸承(FlatNeedle Bearing) 12及套上迫緊環 狀墊片(Ring Type Thrust Gasket) 13。同時,馬達 18 鎖定 在一馬達座(Motor Bracket) 16上,並於馬達18上方鎖定 一光栅(Raster ) 17,光柵17旁並設有一固定在開關座 (Sensor Bracket) 20 上的光電開關(PhotoSensor) 19。 在第1圖中的左右兩側分別設置有圓弧狀側蓋(Side Cover ) 1及3,並於上方以圓弧上蓋(Top Cover ) 2蓋住單 ® 眼相機4及此裝置的其他零件。單眼相機4的位置則以相機 固定架(Camera Fixing Bracket) 31、34 及 37 配合導引塊 (Guiding Block) 30、導引溝(Guiding Slot) 35、38 及 43 作X、Y及Z方向的移動,再以固定帽蓋(Fixing Nut) 32、 固定螺絲(Fixing Screw) 33、36及39分別加以鎖定相機固 定架31、34及37。 第2圖及第3圖所示分別為依據本發明一實施例的以坐式 驅動單眼相機鏡頭伸縮的裝置的組立圖的上視圖(Top View) 及側視圖(Side View )。為簡化圖式,圖2僅示意地繪示出 大齒輪14與小齒輪15互相嵌合的數個齒。如第1圖、第2 6 201017323 • 圖及第3圖所示,定位孔40及41與大齒輪14上的定位銷 10及44相結合,而夾緊針(CHnch%、27、28及 29則設置於套環6及22的内緣,並往内頂住鏡頭5,其中套 環不僅可由兩個半環形套環(Duai Semi_circular Adapting(c〇ntr〇1 Panel) or a computer screen to control a single-eye camera for shooting, all of the main eye cameras can be seen in one eye, and can be used in a fully automatic shooting system. In order to achieve the above object, the present invention provides a device for telescopically driving a single eye head, comprising: a chassis, a collar, a large window wheel, a pinion, and a motor. The collar is placed over the lens of the monocular camera and rests on the large gear. The pinion gear is used to drive the large gear to rotate. Horse, used to drive the pinion to rotate. The chassis is used to carry the core and the fixed monocular camera. In order to make the above features and advantages of the present invention more comprehensible, the following detailed description of the embodiments of the present invention will be described in detail below. [Embodiment] FIG. 1 is a front elevational view (Fr〇ntview) of a device for telescopically driving a monocular camera lens according to an embodiment of the present invention, illustrating a component part of the device of the present invention as a collar The 6 and 22 f beams are on the lens 5 of the monocular camera 4. The collars 6 and 22 are provided with positioning holes (L〇ckH〇ie) and 41'. The entire collars 6 and 22 are seated on the large gear 14, and the positioning pin (Lock Pin) on the large gear 14 〇 and 44 are inserted into the 5 201017323 locating holes 40 and 41 on the collars 6 and 22, respectively. The pinion gear 15 is rotated by the motor 18, and the large gear wheel 14 is rotated by the pinion gear 15, and the ring 5 of the single-eye camera 4 is rotated by the collars 6 and 22 seated on the large gear 14 to achieve the expansion and contraction of the driving lens 5. the goal of. The above is the main part constituting the apparatus of the present invention, and the above parts are placed on the chassis 42. Further, the Rotating Base 9 is locked upward from below the chassis 42 and the Ring Shaft 45 which projects upward from the Swing Base 9 serves as the rotating shaft of the large gear 14. In this embodiment, the 'oilless bush 11 can be embedded between the large gear 14 and the annular shaft 45, and the upper gear 14 can pass through a bearing fixed on the fixing block 7. (Bearing) 8 guides the disk surface of the large gear 14 to rotate. Between the large gear 14 and the horizontal contact surface of the slewing base 9, a flat needle bearing 12 and a Ring Type Thrust Gasket 13 can be placed. At the same time, the motor 18 is locked on a motor bracket 16 and a grating is locked above the motor 18. A grating 17 is disposed adjacent to the grating 17 and is provided with a photoelectric switch (PhotoSensor) fixed on the sensor bracket 20 (Sensor Bracket) 20 ) 19. The left and right sides of the first figure are provided with arc-shaped side covers 1 and 3, and the top cover 2 and the other parts of the device are covered with a top cover 2 (Top Cover) 2 at the top. . The position of the monocular camera 4 is in the X, Y, and Z directions with Camera Fixing Brackets 31, 34, and 37, Guiding Block 30, Guiding Slots 35, 38, and 43. Move, and then fix the camera mounts 31, 34 and 37 with a fixing cap (Fixing Nut) 32 and fixing screws 33, 36 and 39, respectively. 2 and 3 are a top view and a side view, respectively, of an assembly diagram of a device for telescopically driving a monocular camera lens according to an embodiment of the present invention. To simplify the drawing, Fig. 2 only schematically shows a plurality of teeth in which the large gear 14 and the pinion 15 are fitted to each other. As shown in Fig. 1 and 2 6 201017323 • Fig. 3 and Fig. 3, the positioning holes 40 and 41 are combined with the positioning pins 10 and 44 on the large gear 14, and the clamping needles (CHnch%, 27, 28 and 29) Then placed on the inner edge of the collars 6 and 22, and against the lens 5, wherein the collar can be not only two half-rings (Duai Semi_circular Adapting)
Ring) 6及22 (如第1〇圖所示)所組成,亦可為單一環形套 環(An Adapting Ring) 57 (如第4圖所示)。另外,在其他 未繪示的實施例中,套環更可由多數個弧形套環或多數個線 形套環所組成。夾緊針26以彈簧(Spring) 25頂出並以帽蓋 (Nut) 24由後方鎖住。左右擋板(Baffle) 21及23與圓弧 Φ 上蓋2相結合,同時以圓弧狀側蓋1及3封住另外兩面以形 成一密閉的相機室(Camera Housing)。 第4圖至第9圖所示為依據本發明一實施例的以坐式驅動 單眼相機鏡頭伸縮的裝置的主要零件圖。其中,第4圖為單 一套環57的零件上視圖,其具有二個定位孔40及41以及四 個夾緊針26、27、28及29。第5圖為大齒輪14的零件上視 圖及正視剖面圖,並在左右各設有一支定位銷10及44。第6 圖為底盤42的零件上視圖、正視剖面圖及側視剖面圖。如第 1圖及第6圖所示,其左方導引塊30乃用以導引相機固定架 參 31滑動,而右方圓孔(Round Hole) 46乃供小齒輪Μ下半 部的圓形轉鈕(Round Turning Knob) 47穿過並露出於底盤 42的下方。第7圖為迴轉基座9的上視圖、正視圖及側視剖 面圖,其中正視圖的左半部缯·示出迴轉基座9的剖面。如第 1圖及第7圖所示,螺絲由迴轉基座9的底部穿過迴轉基座9 的螺絲孔往上鎖在底盤42的下方’且底盤42中央露出環狀 軸45以作為大齒輪14轉動的轴心。第8圖為小齒輪Η的上 視圖、正視圖及下半部圓形轉鈕47的下視圖。。如第1圖及 . 第8圖所示,轉動位於小齒輪15下半部的圓形轉鈕47,即 ' 能帶動大齒輪14轉動’再透過大齒輪14帶動鎖在鏡頭5上 7 201017323 的套環6及22轉動,即能轉動鏡頭5直到其上死點。此時, 光柵17所偵測到的位置即為控制鏡頭5轉動的起始位置。第 9圖為光柵17的上視圖及側視剖面圖。如第1圖及第9圖所 示,光栅17上的多數個長條形切口即為光電開關19的偵測 位置。 第10圖所示為依據本發明一實施例的以坐式驅動單眼相 機鏡頭伸縮的裝置的雙半環形套環6及22的上視圖。每個半 環形套環6或22上各設置有三個定位孔以取代第4圖中的定 位孔40及41。值得注意的是,雖然此實施例中的套環6及 ❿ 22共具有六個定位孔,但套環6及22與第11圖中的大齒輪 14組裝時只會使用到其中三個定位孔,而其他三個定位孔則 是為了使半環形套環6及22可共用一個塑膠射出模具而設 計。同時,每個半環形套環6及22上亦各設置有兩支夾緊針 26 ' 27 、 28 及 29 。 第11圖所示為依據本發明一實施例的以坐式驅動單眼相 機鏡頭伸縮的裝置的具三定位銷(TriLockPin)的大齒輪14 的上視圖。此實施例採用三定位銷以取代第5圖中的雙定位 銷10及44。如此一來,大齒輪14與第10圖中的套環6及 22組裝時即可穩定地托住位於其上方的套環6及22,以便於 三定位銷與套環6及22内的三個定位孔對齊。 第12圖所示為依據本發明一實施例的以坐式驅動單眼相 機鏡頭伸縮的裝置,以盒子48包覆第1圖、第2圖及第3 圖中所示的單眼相機4及此裝置的其他零件。為簡化圖式, 第12圖中僅繪示出此裝置的盒子48,並省略其他零件。以 上蓋49及盒身50所形成的盒子48可用來取代第1圖、第2 圖及第3圖中所示的由側蓋1及3、上蓋2、擋板21及23 以及底盤42所圍成的密閉相機室。 8 201017323 第13圖所示為依據本發明一實施例的以坐式驅動單眼相 機鏡頭伸縮的裝置,以盒子51包覆第1圖、第2圖及第3 圖中所示的單眼相機4及此裝置的其他零件。為簡化圖式, 第13圖中僅繪示出此裝置的盒子51,並省略其他零件。盒 子51的上方具有開口 52,而盒子51的下方具有螺絲孔53。 上方開口 52可讓第1圖、第2圖及第3圖中所示的單眼相機 4上加裝的閃光燈露出於盒子51外,而下方的螺絲孔53則 可用以將腳架54 (Tripod)鎖定於盒子51底部,同時盒子 51上更可設置有USB插座55及電源插座56。 © 綜合上述,本發明提供一種在單眼相機外面,以坐式間接 驅動單眼相機鏡頭伸縮的裝置。套環直接坐靠在大齒輪上, 因此馬達驅動小齒輪轉動時即可透過小齒輪直接帶動大齒 輪,進而間接轉動套環,以達成鏡頭伸縮的目的。反之,如 果直接驅動鏡頭上的套環,將可能會造成鏡頭歪斜及鏡頭轉 動不確實的結果。 雖然本發明已以實施例揭露如上,然其並非用以限定本發 明,任何所屬技術領域中具有通常知識者,在不脫離本發明 的精神和範圍内,當可作些許的更動與潤飾,因此本發明的 ® 保護範圍當視後附的申請專利範圍所界定者為準。 9 201017323 •【圖式簡單說明】 第1圖所不為依據本發明一實施例的以坐式驅動單眼相機鏡 頭伸縮的裝置的組立圖的正視圖。 第2圖所不為依據本發明一實施例的以坐式驅動單眼相機鏡 頭伸縮的裝置的組立圖的上視圖。 苐3圖所不為依據本發明一實施例的以坐式驅動單眼相機鏡 頭伸縮的裝置的組立圖的側視圖。 φ 第4圖所不為依據本發明一實施例的以坐式驅動單眼相機鏡 頭伸縮的裝置的單一套環的零件上視圖。 第5圖所不為依據本發明一實施例的以坐式驅動單眼相機鏡 頭伸縮的裝置的大齒輪的零件上視圖及正視剖面圖。 第6圖所不為依據本發明一實施例的以坐式驅動單眼相機鏡 頭伸縮的裝置的底細零件上視圖、正視剖面g及側視剖面 圖。 第7圖所示為依據本發明—實施例的以坐式驅動單眼相機鏡 _ 頭伸縮的裝置的迴轉基座的上視圖、正視圖及側視剖面圖。 第8圖所示為依據本發明—實施例的以坐式驅動單眼相機鏡 頭伸縮的裝置的小齒輪的上視圖、正視圖及下半部圓形 的下視圖。 第9圖所示為依據本發明—實施例的以坐式驅動單眼 頭伸縮的裝置的光柵的上視圖及側視剖面圖。 第—10圖所示驗據本發明—實施例的以坐式驅動單眼 鏡頭伸縮的數置的雙半環形套環的上視圖。 第11圖所示為依據本發明一實施例的以坐式驅動單眼相 鏡頭伸縮的裝置的具三定位銷的大齒輪的上視圖。 201017323 第12圖所示為依據本發明一實施例的以坐式驅動單眼相機 鏡頭伸縮的裝置,以盒子包覆單眼相機及此裝置的其他零件。 第13圖所示為依據本發明一實施例的以坐式驅動單眼相機 鏡頭伸縮的裝置,以盒子包覆單眼相機及此裝置的其他零 件,其上方具有開口,而其下方具有螺絲孔,且其設置有USB 及電源插座。 【主要元件符號說明】 ❿ 1、3 :側蓋 2 :上蓋 4:單眼相機 5 :鏡頭 6、22 :套環 7 :固定塊 8 :軸承 ® 9 :迴轉基座 10、44 :定位銷 11 :無給油式襯套 12 :平面針狀軸承 13 :迫緊環狀墊片 14 :大齒輪 15 :小齒輪 16 :馬達座 11 201017323 :光柵 :馬達 :光電開關 :開關座 、23 :擋板 :帽蓋 :彈簧 鲁 、27、28、29 :夾緊針 :導引塊 、34、37 :相機固定架 :固定帽蓋 、36、39 :固定螺絲 、38、43 :導引溝 ' 41 :定位孔 :底盤 :環狀軸 :圓孔 :圓形轉鈕 、51 :盒子 :上蓋 :盒身 52 :開口 12 201017323Ring) 6 and 22 (as shown in Figure 1) can also be a single ring (An Adapting Ring) 57 (as shown in Figure 4). In addition, in other embodiments not shown, the collar may be composed of a plurality of curved collars or a plurality of linear collars. The clamping pin 26 is ejected with a spring 25 and locked by the rear with a cap 24. The left and right baffles 21 and 23 are combined with the circular arc Φ upper cover 2, and the other two faces are sealed by the arcuate side covers 1 and 3 to form a sealed camera housing. 4 to 9 are diagrams showing main parts of a device for telescopically driving a monocular camera lens in accordance with an embodiment of the present invention. 4 is a top view of the component of the single set of rings 57 having two positioning holes 40 and 41 and four clamping pins 26, 27, 28 and 29. Fig. 5 is a top view and a front cross-sectional view of the large gear 14, and a positioning pin 10 and 44 are provided on the left and right sides. Figure 6 is a top plan view, a front cross-sectional view and a side cross-sectional view of the chassis 42. As shown in FIGS. 1 and 6, the left guiding block 30 is for guiding the camera holder 31 to slide, and the right round hole 46 is for the lower half of the pinion. A Turn Turning Knob 47 passes through and is exposed below the chassis 42. Fig. 7 is a top view, a front view and a side cross-sectional view of the swing base 9, wherein the left half of the front view shows a cross section of the swing base 9. As shown in FIGS. 1 and 7, the screw is locked from the bottom of the swing base 9 through the screw hole of the swing base 9 to the lower side of the chassis 42 and the annular shaft 45 is exposed at the center of the chassis 42 as a large gear. 14 axis of rotation. Fig. 8 is a bottom view of the pinion gear, a front view, and a lower view of the lower half circular knob 47. . As shown in Fig. 1 and Fig. 8, the circular knob 47 located in the lower half of the pinion 15 is rotated, that is, 'can drive the large gear 14 to rotate' and then the large gear 14 is driven to lock on the lens 5 7 201017323 When the collars 6 and 22 are rotated, the lens 5 can be rotated until its top dead center. At this time, the position detected by the grating 17 is the starting position for controlling the rotation of the lens 5. Figure 9 is a top view and a side cross-sectional view of the grating 17. As shown in Figures 1 and 9, a plurality of elongated slits on the grating 17 are the detection positions of the photoelectric switch 19. Figure 10 is a top plan view of the double half annular collars 6 and 22 of the device for telescoping a single eye camera lens in accordance with an embodiment of the present invention. Each of the semi-annular collars 6 or 22 is provided with three positioning holes instead of the positioning holes 40 and 41 in Fig. 4. It should be noted that although the collar 6 and the cymbal 22 in this embodiment have a total of six positioning holes, only the three positioning holes are used when the ferrules 6 and 22 are assembled with the large gear 14 in FIG. The other three positioning holes are designed to allow the semi-annular collars 6 and 22 to share a plastic injection mold. At the same time, each of the semi-annular collars 6 and 22 is also provided with two clamping pins 26' 27 , 28 and 29 . Fig. 11 is a top plan view of a large gear 14 having a three-position pin (TriLockPin) for a device for telescopically driving a monocular camera lens telescope according to an embodiment of the present invention. This embodiment employs three positioning pins instead of the double positioning pins 10 and 44 in Fig. 5. In this way, when the large gear 14 is assembled with the collars 6 and 22 in FIG. 10, the collars 6 and 22 located above it can be stably supported, so as to facilitate the three positioning pins and the three of the collars 6 and 22 The positioning holes are aligned. 12 is a view showing a telescopic device for telescopically driving a monocular camera lens, and covering the monocular camera 4 shown in FIG. 1, FIG. 2, and FIG. 3 with the box 48 and the device according to an embodiment of the present invention. Other parts. To simplify the drawing, only the box 48 of this device is shown in Fig. 12, and other parts are omitted. The upper cover 49 and the box 48 formed by the case 50 can be used to replace the side covers 1 and 3, the upper cover 2, the flaps 21 and 23, and the chassis 42 as shown in Figs. 1, 2, and 3. Into the closed camera room. 8 201017323 FIG. 13 is a view showing a telescopic device for telescopically driving a monocular camera lens according to an embodiment of the present invention, and covering the monocular camera 4 shown in FIGS. 1 , 2 and 3 with a box 51 and Other parts of this device. To simplify the drawing, only the case 51 of this device is shown in Fig. 13, and other parts are omitted. The box 51 has an opening 52 above it, and the box 51 has a screw hole 53 below it. The upper opening 52 allows the flash attached to the monocular camera 4 shown in FIGS. 1 , 2 and 3 to be exposed outside the case 51, and the lower screw hole 53 can be used to mount the tripod 54 (Tripod). It is locked to the bottom of the box 51, and the box 51 can be further provided with a USB socket 55 and a power socket 56. © In summary, the present invention provides a device for telescopically driving a monocular camera lens in a telescopic manner on the outside of a monocular camera. The collar directly rests on the large gear. Therefore, when the motor drives the pinion, the pinion can directly drive the large gear through the pinion, thereby indirectly rotating the collar to achieve the purpose of the lens expansion and contraction. Conversely, if you directly drive the collar on the lens, it may cause the lens to be skewed and the lens to rotate inaccurately. Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention, and those skilled in the art can make some modifications and refinements without departing from the spirit and scope of the present invention. The scope of the present invention is defined by the scope of the appended claims. 9 201017323 • [Simplified Schematic Description] Fig. 1 is a front elevational view showing an assembly of a device for telescopically driving a monocular camera lens according to an embodiment of the present invention. Fig. 2 is a top plan view showing an assembly of a device for telescopically driving a monocular camera lens according to an embodiment of the present invention. Figure 3 is a side view of an assembled view of a device for telescopically driving a monocular camera lens telescope according to an embodiment of the present invention. φ Fig. 4 is a top plan view of a single set of rings of a device for telescopically driving a monocular camera lens telescope according to an embodiment of the present invention. Figure 5 is a top plan view and a front cross-sectional view of a large gear of a device for telescopically driving a monocular camera lens telescope according to an embodiment of the present invention. Fig. 6 is a top plan view, a front cross-sectional view, and a side cross-sectional view of a bottom part of a device for telescopically driving a monocular camera lens according to an embodiment of the present invention. Fig. 7 is a top plan view, a front elevational view and a side cross-sectional view showing a swivel base of a device for telescopically driving a monocular camera lens according to the present invention. Fig. 8 is a top plan view, a front view and a bottom view of the lower half of the pinion of the apparatus for telescopically driving a monocular camera lens according to the present invention. Fig. 9 is a top plan view and a side cross-sectional view showing a grating of a device for telescopically driving a single eye in accordance with an embodiment of the present invention. Fig. 10 is a top view of the double half annular collar of the present invention, which is a telescopically driven single eye lens telescopic. Figure 11 is a top plan view of a bull gear having three positioning pins in a device for telescoping a monocular phase lens telescopic according to an embodiment of the present invention. 201017323 Fig. 12 is a view showing a device for telescopically tilting a single-lens camera lens with a seat-mounted single-lens camera and other components of the device in accordance with an embodiment of the present invention. Figure 13 is a view showing a device for telescopically driving a monocular camera lens telescope according to an embodiment of the present invention, the box-covered single-eye camera and other components of the device having an opening above the screw hole and a screw hole therebelow, and It is equipped with a USB and power outlet. [Main component symbol description] ❿ 1, 3: Side cover 2: Upper cover 4: Monocular camera 5: Lens 6, 22: Collar 7: Fixed block 8: Bearing® 9: Slewing base 10, 44: Locating pin 11: Oil-free bushing 12: Plane needle bearing 13: Forced ring gasket 14: Large gear 15: Pinion gear 16: Motor seat 11 201017323: Raster: Motor: Photoelectric switch: Switch seat, 23: Baffle: Cap Cover: Spring Lu, 27, 28, 29: Clamping pin: Guide block, 34, 37: Camera holder: Fixed cap, 36, 39: Fixing screw, 38, 43: Guide groove ' 41 : Positioning hole : Chassis: Ring shaft: Round hole: Round knob, 51: Box: Top cover: Box 52: Opening 12 201017323
53 :螺絲孔 54 :腳架 55 : USB插座 56 :電源插座 57 :單一環形套環 1353 : Screw hole 54 : Tripod 55 : USB socket 56 : Power socket 57 : Single ring collar 13