M333403 八、新型說明: 【新型所屬之技術領域】 " 本創作係有關於一種斗型零件供給器,以平面看來大 ’ 致呈長圓形,特別是有關於具有大體上呈橢圓狀的橢圓型 ’ 斗體零件供給器。 【先前技術】 I 按,斗型零件供給器具有壓電式振盪裝置,相對於振 動中心,斗體内侧的周緣呈螺旋梯式,係隨著朝上向外擴 開形成斷面呈逆圓錐梯形的斗體(以下,係稱螺旋梯式斗 體)。 同時,所述斗體内側的螺旋梯式周緣具有零件搬送 道,係以大體上同樣的直徑形成在斗型零件供給器的斗體 (以下,係稱圓筒斗體)。 胃由於在此種的斗型零件供給器係以壓電式的振盪裝置 作動,零件投入在圓筒斗體的底部,從該斗體底部沿著螺 旋梯式的零件搬送道,慢慢依序地搬送,直到連接在斗體 出口的直線型零件供給器的搬送執道,以將零件依序地搬 送到預定的位置。 因此,使用螺旋梯式斗體和圓筒斗體時,在斗體外周 部,即漸漸往外侧移動,如果打算設置多數台此種斗型零 5 M333403 件供給器,則由於螺旋梯式斗體和圓筒斗體最大外徑的限 制,因此無法緊湊地設置多數台斗型零件供給器。 如果此種螺旋梯式斗體和圓筒斗體的最大外徑設計成 很小的話,對投入斗體底部的零件會相對地減少。斗體的 容量如果減少,則斗體容量、零件容量及零件重量等,會 有不能相互配合推進的問題,進而會導致供給器之零件搬 送能力變得不穩定。 故而,前述之斗型零件供給器有再加以改進之必要。 【新型内容】 因此,本創作為解決上述的問題點,提供了具有平面 來看大體上呈長圓狀的橢圓斗體的斗型零件供給器,橢圓 斗體係為螺旋梯式斗體或圓筒斗體。 故,具體而言,首先針對第一斗型零件供給器的螺旋 梯式斗體,平面看來呈長圓狀,由圓弧部和直線部構成橢 圓螺旋梯式斗體;同時,第二斗型零件供給器的圓筒斗體, 平面看來如橢圓形狀,由橢圓部和圓孤部構成的橢圓圓筒 斗體;不但每一斗型零件供給器的設置空間減少,更能有 效率地應用多數台斗型零件供給器的整體設置空間。 再者,對斗型零件供給器設定有關本創作橢圓螺旋梯 式斗體和橢圓圓筒斗體,將零件投入該斗體之後,再加上 6 M333403 如電磁式壓電裝置等的振盪裝置使其作動的話,投入在斗 體底盤的零件,在沿著底盤週邊外周部大致呈扁平螺旋圓 弧且較淺的凹狀底部開始盤旋。 零件到達搬送入口後,依序從斗體内側周緣的零件搬 送道,沿著向外周緣的零件搬送路慢慢從裡面隨之上升搬 送。 同時,在橢圓圓筒斗體的狀態下,零件從斗體底部的 搬送入口至零件出口,係從下層内側周紉的零件搬送道, 向上層内側周緣方面的零件搬送道慢慢隨之上升搬送。. 並且,最終零件從末端部的零件出口交由直線型零件 供給器的零件搬送繼續供給搬送。 【實施方式】 關於本創作藉以達到上述目的之技術手段,茲以下列 實施型態配合圖示於下文作詳細說明,俾令鈞上深入暸解 並認同之。 本創作並未限定可以使用的電子零件型式,而較佳適 用的電子零件,例如電容器、電感器、發光二極體(led)、 表面聲波單元(surface acoustic wave element)以及半導體 積體電路(1C)等等。特別是適用在0.001〜10立方毫米以 下尺寸的微細零件,而能依序地且以既定的姿態運送供給 M333403 這樣的微細零件。 . 纟先,請參相1及圖2,係分別表示本創作第一實 ,_的斗型零件供給器的立體圖及平面圖;本實施例的斗 .體則’以其平面圖所視,係分為圓弧部X及直線部γ,若 由其出口部的剖視圖來看,平面大體上係呈長圓狀的_ 斗體(以下,稱為長圓斗體),而且,其㈣緣會向外周緣 ,擴開’慢慢地形成扁平螺旋狀的傾斜台階結構,而斗體斷 面即形成逆圓錐梯形狀的構造。 、,長圓斗體m内周部形成的傾斜台階構造之零件搬送 …。制文長圓斗體B1中間部形成的零件搬送入口 1,到 長圓斗體B1外周部’以扁平螺旋狀緩慢地運送1周,並形 成傾斜角度0。 、、長圓斗體m外周部形成的傾斜台階構造之零件搬送 .#❹,在與運送1周的内周部的零件搬送路μ連接處,到 ..該長圓斗體B1最相部,以解螺餘緩慢地運送!周, $錢斜角度0 ’將直角剪掉之末端部卿成長圓斗體 B1的零件出口 2。 、、广個内外2周周圍的零件搬送路M、N,由於如同圖2 上W ^ ’大體上係以扁平螺旋狀JL平滑地長圓 狀之輪廓線所形成。 以圖2說明,從斗體中心隔開的Η·Η線(橫轴)及料 8 M333403 線(縱軸)之交點為座標韩,向H-H線(橫軸)右側的正方向之 距離a,V-V線(縱轴)前方面的負方向之距離b的位置01 為中心,即可描齋出以H-H線的正方向半徑R1的圓弧壁 XI ;另,向H-H線(橫軸)右侧的正方向向到距離c,V-V 線的負方向距離d的位置02為中心,即描繪出半徑R3的 " 圓弧壁X3和以半徑R5的圓弧壁X5。 同時,從斗體中心向H-H線上負方向(左側)距離e的 鲁 位置03為中心,描繪出在H-H線負方向(左側)半徑R2的 圓弧壁X2、半徑R4的圓弧壁X4及半徑R6的圓弧壁X6。 並且,把圓孤壁XI後部的圓弧邊,轉向零件搬送入 口 1朝H-H線的一側及並行地描繪出的直線壁Y1,大體上 連接到V-V線上延設而連結。 同時,以直線壁Y2斜向連結圓弧壁XI前部的圓弧邊 以及圓弧壁X2前部的圓弧邊。同樣地,圓弧壁X2後部的 — 圓弧邊以及圓弧壁X3後部的圓弧邊,以與H-H線平行的 直線壁Y3連結;同時,圓弧壁X3前部的圓弧邊以及圓弧 壁X4前部的圓弧邊,以與H-H線平行的直線壁Y4連結; 圓弧壁X4後部的圓弧邊以及圓弧壁X5後部的圓弧邊,以 與H-H線平行的直線壁Y5連結;在最後時,從圓弧壁X6 後部方面的圓弧邊朝向零件出口 2,以和H-H線大致平行 的直線壁Y7到V-V線上延設做連接。由於如修飾直角邊 9 M333403 和以平面圖來看,係大體上以扁平螺旋狀形成如同小金 幣形狀’而在其内周壁和外周壁之間,在適宜地幅度内外 可構成雙重的零件搬送路Μ、N。 口此對内周壁的零件搬送路M及外周壁的零件搬送 路Ν而吕,直線狀的傾斜台階結構之斗體前後位置幅度比 ’較窄,同時,圓弧狀的傾斜台階結構之斗體左右兩側位置 幅度的比較寬廣的零件搬送路Μ、Ν。 "月同蚪芩考圖3、圖4及圖5,係分別表示圖2中Η-!! 、、友戴面U面圖、圖2中^/^線截面之剖面圖以及本創作 具有壓电1置中v-v線截面之剖面圖;長圓斗體β1斗體 底部3形狀,係從斗體底盤3外周部的坡狀流暢地漸呈略 微高起的山脊狀,而形成高漲凸出的外型。 斗體底盤3的外周部形成比較淺的凹狀型底部4,斗 ⑩體底^ 3使王體投入零件(圖未示),能一邊繞扁平螺旋狀 的圓弧且-邊盤旋,由於形成如圖2依序朝箭頭方向以 D4轉考,凹狀底部4係從零件搬送入口丨依序朝箭頭方 向D1〜D4轉彎搬送零件。 斗體底盤3中心位置係穿設可取放物體的通孔5,其 周邊係形成環狀的平坦部6。 ’、 長圓斗體B1的底部並具有一環狀的搶托部7。 其次,請參考圖4,本創作之壓電裝置類型的斗型零 M333403 件供給器,其與上述㈣狀销w _勒類似。 圓盤型的基座8之表面相部之3〜4#分位置朝上突 設突出部9,在其間係凹設凹陷部1〇。 在適度的傾斜角度係設置壓電裝置u, 突出部9連接,並夢由螺絲n + ^ 朝 工糟由螺絲13夾以金屬件12固定。 圓盤型的頂板14之底面外周部的3〜4等分,係設置 朝下的突出部15。 板狀彈片16係藉由墊圈17與朝下的突出们5連接, 其上端部關由金屬件12以螺絲13加上設置在 圈17而固定。 1 同蚪板狀彈片16下端部固定在壓電裝置上上端部, 其間係設置塾圈17 ,並藉由金屬件12連接到壓電裝置^ 後部,同日夺,在板狀彈片16前部及墊目17以螺釘螺合之 後’再鎖上金屬件18,藉由螺絲13穿插通過壓電裝置u 後部及金屬件18以螺合固定。 板狀彈片16中間部份的内側和外侧係凹^凹陷部IQ。 失緊螺栓20係穿經該長圓斗體⑴的通孔5,結合從頂板 14中心螺合到下半部的螺孔21。 從頂板14外周部的圓筒狀的邊蓋22,其下端部與基 座8的突起部9外週邊以螺釘23固定。 硬質橡膠材質的腳架24,係為了固定為腳架24下端 11 M333403 部所附設的底板25,固定螺母27係從下端部穿插過基座8 的凹部10,並與螺絲26上端部螺合。 再者,在基台28上設置電磁類型的振盪裝置,且包藏 有壓電裝置類型振盪裝置的斗型零件供給器,在斗型零件 • 供給器的頂板14設置本創作之長圓斗體B1,將零件投入 • 斗體之後,經由上述的振盪裝置使投入在斗體底盤3的零 件,在扁平螺旋狀的圓弧開始盤旋,斗體底盤3週邊外周 ❿ 部形成比較淺的凹狀底部4係沿著如圖2箭頭方向D1〜D4 轉彎。在凹狀底部4内且到達零件搬送入口 1的零件,從 長圓斗體B1内周部的零件搬送路Μ,朝外周部的零件搬 送路Μ慢慢被上升搬送,最後在末端部零件出口 2的零件 會由直線型零件供給器(圖未示)接續搬送供給。 其次,請參考圖6,係表示的本創作的第2實施例的 平面圖本貫施例的斗體Β 2具有擴圓部Ζ和圓孤部X ^並 ® 將出口部剪除,平面看來,形成大致呈橢圓形狀的橢圓斗 體(以下,稱為橢圓斗體)。 圓弧部X,係與第1實施例長圓斗體Β1的圓弧狀的圓 弧壁XI〜Χ6大體上相同的結構,而橢圓部Ζ係替換在第 1實施例所構成的直線部Υ,其結構大致相同,故不再贅 述。 因此,内周部的零件搬送路Μ和外周部的零件搬送路 12 M333403 N,斗體幅度比較窄的前後位置係由長軸橢圓形狀的傾斜 台階所構成’同時,斗體幅度比較寬廣的左右兩側位置係 由半徑較小的短圓形狀的傾斜台階所構成的零件搬送路 Μ、N。 再者,請爹考圖7,係表示本創作的第3實施例的斜 視圖,本實施例的圓筒斗體Β3、结構與第!實施例結構類 似,具有圓弧部X和直線部γ,形成大致呈長圓柱型的擴 圓斗體(以下’稱為圓筒長圓斗體),而且,其内周部,從 圓筒長圓斗體底部的零件搬送入口!到上端外周部的圓筒 長圓斗體零件出口 2係具相同直徑,2周的長度於上和下 方向的扁平螺旋狀的傾斜台階係構成零件搬送路⑽。 #他的構成’與第1實施例的長圓斗體B1具有同樣的 構造,因此圖7的結構即不再贅述。 ㈣,請參考圖8,絲林㈣第4實施例的平面 圖,本實施例的圓筒斗體B4係與第2實施例的結構類似, 具有橢圓部Z和圓弧部X,形成平面大致呈擴圓形狀的擴 圓斗體(以下,稱為圓筒橢圓斗體),而且,其内周部,從 圓筒橢圓斗體底部的零件搬送入口!到上端外周部的零件 出口 2具有同樣直徑,2周的長度於上和下方向的扁^螺 旋狀的傾斜台階係構成零件搬送路M,n。 其他的構成,與第2實施例的長圓斗體B2具有同樣的 13 M333403 構造,因此圖8的結構即不再贅述。 本創作,如上述斗型零件供給器的斗體Bl、B2和圓 筒斗體B3、B4,平面看來構成大致呈橢圓形狀的橢圓斗 體,更具體地說,首先,平面圖中具有圓孤部X和直線部 • Y的長圓狀斗型零件供給器的斗體B1和圓筒斗體B3,成 • 為第一橢圓斗體,斗型零件供給器的斗體B2和圓筒斗體 B4係為第二橢圓斗體,平面圖中係具有圓形的圓弧X及橢 _ 圓部Z ;因為每單一個斗型零件供給器的設置空間,能使 多數台相互鄰接的斗型零件供給器,在空間上有效率地設 置。 在其内部,橢圓斗體若為長圓斗體B1和圓筒長圓斗體 B3時,因為零件搬送路Μ、N具有直線部Y,可限制呈不 同大小和形態的零件的排列搬送,以區分零件安悲的零件 搬送裝置,安裝在直線部Υ之後,或者,發揮對零件的機 ® 器加工作業或上述作業性出色的效果。 以上所述實施型態之揭示係用以說明本創作,並非用 以限制本創作,故舉凡數值之變更或等效元件之置換仍應 隸屬本創作之範疇。 由以上詳細說明,可使熟知本項技藝者明暸本創作的 確可達成前述目的,實已符合專利法之規定,爰提出專利 申請0 14 M333403 【圖式簡單說明】 圖1’係表示本創作第一實施例的斗型零件供給器立體圖; 圖2’係表示本創作第一實施例的斗型零件供給器平面圖; 圖3 ’係表示圖2中Η-Η線切面之剖面圖; 圖4,係表示圖2令V-V線切面之剖面圖; 圖5,係.表示本創作具有壓電裝置中ν—ν線切面之剖面圖; 圖6 ’係表示本創作的第2實施例的平面圖; 圖7 ’係表示本創作的第3實施例的部分立體圖;以及 圖8,係表示本創作的第4實施例的部分立體圖。 【主要元件符號說明】 1 零件搬送入口 2 零件出口 3 底盤 4 底部 5 通孔 6 平坦部 7 搶托部 8 基座 9 凸出部 10 凹陷部 11 壓電裝置 12 金屬件 13 螺絲 14 頂板 15 凸出部 16 板狀彈片 17 墊圈 18 金屬件 M333403M333403 VIII. New description: [New technical field] [This book is about a bucket-type parts feeder, which looks large in the plane's shape, especially in the shape of a substantially elliptical shape. Elliptical 'body part feeder. [Prior Art] I Press, the bucket type part feeder has a piezoelectric oscillating device, and the circumference of the inner side of the bucket body is spirally laddered with respect to the center of the vibration, and is expanded upwards and outwards to form an inverted conical trapezoidal shape. The body (hereinafter, referred to as a spiral ladder body). At the same time, the spiral ladder type inner side of the bucket body has a component conveying path, and is formed in a bucket body of the bucket type component feeder (hereinafter referred to as a cylinder body) with substantially the same diameter. The stomach is operated by a piezoelectric oscillating device in such a bucket type component feeder, and the components are placed at the bottom of the cylinder body, and the parts are conveyed from the bottom of the bucket body along the spiral ladder type, and slowly The conveyance is carried out until the conveyance path of the linear component feeder connected to the bucket outlet is carried out to sequentially transport the components to a predetermined position. Therefore, when the spiral ladder body and the cylinder body are used, the outer circumference of the bucket body is gradually moved outward, and if a plurality of such bucket type zero 5 M333403 feeders are intended to be provided, the spiral ladder body is used. Since the maximum outer diameter of the cylinder body is limited, it is not possible to provide a large number of bucket type parts feeders compactly. If the maximum outer diameter of the spiral ladder body and the cylinder body is designed to be small, the parts to the bottom of the bucket body are relatively reduced. If the capacity of the bucket body is reduced, the bucket capacity, the component capacity, and the weight of the component may not advance each other, and the component transporting ability of the feeder may become unstable. Therefore, the aforementioned bucket type component feeder has to be further improved. [New content] Therefore, in order to solve the above problems, the present invention provides a bucket type component feeder having an elliptical bucket body which is substantially oblong in plan view, and the elliptical bucket system is a spiral ladder bucket body or a cylinder bucket body. Therefore, specifically, for the spiral ladder body of the first bucket type component feeder, the plane appears to be oblong, and the elliptical spiral ladder body is formed by the arc portion and the straight portion; meanwhile, the second bucket type The cylinder body of the parts feeder, which looks like an elliptical shape in plan, has an elliptical cylinder body composed of an elliptical portion and a round orphan portion; not only the space for installation of each bucket type feeder is reduced, but also can be applied more efficiently. The overall installation space of most bucket type parts feeders. Furthermore, the trap type component feeder is set with the elliptical spiral ladder body and the elliptical cylinder body, and after the parts are put into the bucket body, an oscillation device such as an electromagnetic piezoelectric device such as 6 M333403 is added. When this is actuated, the parts that are placed in the chassis of the bucket are hovered at a flat bottom having a substantially flat spiral arc and a shallow concave bottom portion around the periphery of the chassis. After the parts arrive at the transfer entrance, the parts are transported from the parts on the inner side of the inner side of the bucket, and the parts are transported along the outer peripheral edge and slowly ascended from the inside. At the same time, in the state of the elliptical cylinder body, the parts are transported from the bottom of the bucket to the part outlet, and the parts are transported from the inner side of the lower layer, and the parts transport path on the inner side of the upper layer is gradually raised and transported. . Then, the final part is transferred from the part exit of the end part to the part of the linear part feeder, and the supply is continued. [Embodiment] The technical means by which the author has achieved the above objectives are described in detail below with reference to the following embodiments, and are further understood and agreed upon. This creation does not limit the types of electronic components that can be used, but preferred electronic components such as capacitors, inductors, LEDs, surface acoustic wave elements, and semiconductor integrated circuits (1C) )and many more. In particular, it is suitable for fine parts of a size of 0.001 to 10 mm 3 or less, and can supply fine parts such as M333403 in a predetermined posture and in a predetermined posture. First, please refer to Fig. 1 and Fig. 2, which are respectively a perspective view and a plan view of the bucket type component feeder of the present invention, and the bucket body of the present embodiment is viewed from the plan view. When the circular arc portion X and the straight portion γ are viewed from a cross-sectional view of the outlet portion, the plane is substantially an elongated circular body (hereinafter referred to as a long round body), and the (four) edge is outwardly peripheral. , expanding the 'slowly forming a flat spiral-shaped inclined step structure, and the cross-section of the bucket body forms an inverted cone-shaped structure. , the parts of the inclined step structure formed by the inner circumference of the oblong body m are transported. The component transfer inlet 1 formed in the middle portion of the long circular bucket body B1 is slowly conveyed in a flat spiral shape for one week to the outer peripheral portion of the long circular bucket body B1, and an inclination angle of 0 is formed. And the parts of the inclined step structure formed by the outer circumference of the long round body m are conveyed. #❹, at the end of the part transport path μ at the inner peripheral portion of the one-week transport, to the end of the long round body B1, Unloading the screw slowly! Week, $ money oblique angle 0 ′ will cut off the right end of the end of the growth of the round body B1 part of the exit 2. The parts transport paths M and N around the inside and outside of the wide circumference are formed by the contour line of the flat spiral JL which is smoothly rounded as shown in Fig. 2 . As shown in Fig. 2, the intersection of the Η·Η line (horizontal axis) and the material 8 M333403 line (vertical axis) separated from the center of the bucket body is the coordinate a, and the distance a in the positive direction to the right side of the HH line (horizontal axis), The position 01 of the distance b in the negative direction of the front side of the VV line (vertical axis) is the center, and the arc wall XI of the radius R1 in the positive direction of the HH line can be traced; the other side is the right side of the HH line (horizontal axis) The positive direction is to the distance c, and the position 02 of the negative direction distance d of the VV line is the center, that is, the " arc wall X3 of the radius R3 and the arc wall X5 of the radius R5 are drawn. At the same time, from the center of the bucket to the negative position (left side) of the HH line, the distance from the lu position 03 of the e is the center, and the arc wall X2 of the radius R2 in the negative direction (left side) of the HH line, the arc wall X4 of the radius R4, and the radius are drawn. Arc wall X6 of R6. Further, the arc side of the rear portion of the round wall XI is turned to the side of the H-H line of the component transport inlet 1 and the straight wall Y1 drawn in parallel, and is connected to the V-V line to be connected and connected. At the same time, the arc side of the arc wall XI and the arc side of the front side of the arc wall X2 are obliquely connected by the straight wall Y2. Similarly, the arc side of the rear part of the arc wall X2 and the arc side of the rear part of the arc wall X3 are connected by a straight wall Y3 parallel to the HH line; at the same time, the arc side and the arc of the front part of the arc wall X3 The arc side of the front portion of the wall X4 is connected by a straight wall Y4 parallel to the HH line; the arc side of the rear portion of the arc wall X4 and the arc side of the rear portion of the arc wall X5 are connected by a straight wall Y5 parallel to the HH line. At the end, from the arc side of the rear side of the arc wall X6 toward the part outlet 2, the line is extended on the straight line Y7 to VV line substantially parallel to the HH line. Due to the modification of the right-angled side 9 M333403 and in plan view, it is formed in a flat spiral shape like a small gold coin shape, and between the inner peripheral wall and the outer peripheral wall, a double-part transporting path can be formed within a suitable range. , N. In this case, the parts transport path M and the outer peripheral wall of the inner peripheral wall are conveyed by the road, and the linear inclined step structure has a narrower front-to-back position ratio, and the arc-shaped inclined step structure is formed. The parts with a wide range of positions on the left and right sides are transported by rollers and rafts. "月同蚪芩考图3, Figure 4 and Figure 5, respectively, shows the Η-!! in Figure 2, the U-face diagram of the friend wearing surface, the cross-section of the ^/^ line section in Figure 2, and the creation Piezoelectric 1 is a cross-sectional view of the vv line section; the shape of the bottom 3 of the long-circle body β1 is a ridge-like shape that gradually rises from the slope of the outer peripheral portion of the chassis 3, and forms a raised bulge. Appearance. The outer peripheral portion of the bucket body 3 forms a relatively shallow concave bottom portion 4, and the bottom portion of the bucket body 10 allows the king body to be put into a part (not shown), and can be wound around a flat spiral-shaped arc and the side is spiraled due to formation. As shown in Fig. 2, the test is performed in the direction of the arrow in the direction of the arrow D4, and the concave bottom portion 4 is turned from the component transfer inlet in the direction of the arrow D1 to D4 to convey the parts. The center position of the bucket chassis 3 is provided with a through hole 5 through which an object can be taken, and the periphery thereof forms an annular flat portion 6. ', the bottom of the long round body B1 has an annular grabbing portion 7. Next, referring to Fig. 4, the bucket type zero M333403 piece feeder of the piezoelectric device type of the present invention is similar to the above (four) pin w _le. The protruding portion 9 is protruded upward from the 3 to 4# position of the surface portion of the disk-shaped susceptor 8, and the depressed portion 1 is recessed therebetween. The piezoelectric device u is disposed at a moderate tilt angle, and the projections 9 are connected, and the dream is fixed by the metal member 12 by the screw 13 from the screw n + ^ toward the work. The outer peripheral portion of the bottom surface of the disk-shaped top plate 14 is divided into three to four portions, and the projecting portion 15 facing downward is provided. The plate-like elastic piece 16 is connected to the downward projection 5 by a washer 17, and the upper end portion thereof is fixed by the metal member 12 with the screw 13 added to the ring 17. 1 The lower end portion of the slab-shaped elastic piece 16 is fixed on the upper end portion of the piezoelectric device, and the cymbal ring 17 is disposed therebetween, and is connected to the rear portion of the piezoelectric device by the metal member 12, and is captured at the front of the slab-shaped elastic piece 16 and After the pad 17 is screwed, the metal member 18 is re-locked, and the screw 13 is inserted through the rear portion of the piezoelectric device u and the metal member 18 to be screwed and fixed. The inner side and the outer side of the middle portion of the plate-like elastic piece 16 are recessed and recessed. The bolts 20 are threaded through the through holes 5 of the long bucket body (1), and are coupled to the screw holes 21 screwed from the center of the top plate 14 to the lower half. The cylindrical side cover 22 from the outer peripheral portion of the top plate 14 is fixed at its lower end portion to the outer periphery of the projection portion 9 of the base 8 by a screw 23. The hard rubber-made tripod 24 is fixed to the bottom plate 25 attached to the lower end 11 M333403 of the stand 24, and the fixing nut 27 is inserted through the recess 10 of the base 8 from the lower end portion, and is screwed to the upper end portion of the screw 26. Further, an electromagnetic type oscillating device is disposed on the base 28, and a bucket type component feeder including a piezoelectric device type oscillating device is disposed, and the long round body B1 of the present invention is disposed on the top plate 14 of the bucket type component supplier. After the components are placed in the body, the components that are placed in the bucket chassis 3 are spirally wound in a flat spiral arc through the above-described oscillating device, and a shallow concave bottom portion is formed on the outer peripheral portion of the bucket chassis 3. Turn along the direction of the arrows D1 to D4 as shown in Figure 2. The parts that have reached the component transfer inlet 1 in the concave bottom portion 4 are transported from the parts in the inner peripheral portion of the oblong bucket body B1, and are gradually lifted and transported toward the component transport path in the outer peripheral portion, and finally at the end portion part outlet 2 The parts are continuously transported and supplied by a linear part feeder (not shown). Next, referring to Fig. 6, the plan view of the second embodiment of the present invention shows a body Β 2 having a rounded portion Ζ and a rounded portion X ^ and ® cut off the outlet portion, in plan view, An elliptical body (hereinafter referred to as an elliptical body) having a substantially elliptical shape is formed. The arc portion X is substantially the same as the arcuate arc walls XI to Χ6 of the long circular body 第1 of the first embodiment, and the elliptical portion 替换 is replaced by the straight portion 构成 formed by the first embodiment. The structure is roughly the same and will not be described again. Therefore, the component transport path of the inner peripheral portion and the component transport path 12 M333403 N of the outer peripheral portion have a narrow front and rear position of the bucket body, which is formed by an inclined step having a long-axis elliptical shape, and the bucket body width is relatively wide. The position on both sides is a part conveying path N, which is composed of a short-circular inclined step having a small radius. Further, please refer to Fig. 7, which is a perspective view showing a third embodiment of the present creation, and the cylindrical body 3 of the present embodiment, the structure and the first! The embodiment has a structure similar to that of the circular arc portion X and the straight portion γ, and forms a substantially round cylindrical body (hereinafter referred to as a cylindrical long round body), and the inner peripheral portion thereof is long from the cylinder. The parts at the bottom of the body are transported to the entrance! The cylinder to the outer peripheral portion of the upper end is provided with the same diameter, and the flat spiral-shaped inclined step having a length of two weeks in the upper and lower directions constitutes a component conveying path (10). The structure of #他其" has the same structure as that of the long circular body B1 of the first embodiment, and therefore the structure of Fig. 7 will not be described again. (4) Referring to Fig. 8, the plan view of the fourth embodiment of the silk forest (four), the cylindrical body B4 of the present embodiment is similar to the structure of the second embodiment, and has an elliptical portion Z and a circular arc portion X, and the plane is substantially The rounded shape of the rounded shape (hereinafter referred to as a cylindrical elliptical body), and the inner peripheral portion thereof is conveyed from the parts at the bottom of the cylinder elliptical body! The component outlets 2 to the outer peripheral portion of the upper end have the same diameter, and the inclined steps of the two spiral lengths in the upper and lower directions constitute the component conveying path M, n. The other configuration has the same structure as the 13 M333403 of the long circular bucket B2 of the second embodiment, and therefore the structure of Fig. 8 will not be described again. The creation, such as the bucket bodies B1, B2 and the cylinder bodies B3, B4 of the bucket type component feeder described above, constitutes an elliptical bucket body having a substantially elliptical shape in a plane, and more specifically, first, a circle is formed in a plan view. The body B and the cylinder body B3 of the long round bucket type component feeder of the portion X and the straight portion • Y are the first elliptical body, the bucket body B2 of the bucket type component feeder, and the cylinder body B4 It is a second elliptical body, and has a circular arc X and an ellipse_round Z in the plan view; because each single bucket type supplier provides space for installation, the bucket type feeders which are adjacent to each other , set up efficiently in space. In the case where the elliptical body is the long round body B1 and the cylindrical long round body B3, since the parts conveying path and the N have the straight portion Y, the arrangement and transportation of the parts of different sizes and shapes can be restricted to distinguish the parts. The accommodating part transfer device is installed after the straight line Υ, or it is effective in machining the parts of the parts or the above workability. The above description of the embodiments is intended to be illustrative of the present invention and is not intended to limit the present invention, so any change in value or replacement of equivalent elements should still fall within the scope of the present invention. From the above detailed description, it will be apparent to those skilled in the art that the present invention can achieve the above-mentioned objectives, and has already met the requirements of the Patent Law, and has filed a patent application 0 14 M333403 [Simple Description of the Drawing] Figure 1' shows the creation of the first Fig. 2' is a plan view showing the bucket type part feeder of the first embodiment of the present invention; Fig. 3' is a sectional view showing the Η-Η line cut surface of Fig. 2; Fig. 2 is a cross-sectional view showing a VV line cut surface; Fig. 5 is a cross-sectional view showing a ν-ν line cut surface in the piezoelectric device; Fig. 6' is a plan view showing a second embodiment of the present invention; 7' is a partial perspective view showing a third embodiment of the present creation; and FIG. 8 is a partial perspective view showing a fourth embodiment of the present creation. [Main component symbol description] 1 Part transfer inlet 2 Part exit 3 Chassis 4 Bottom 5 Through hole 6 Flat part 7 Grab part 8 Base 9 Projection part 10 Recessed part 11 Piezo device 12 Metal part 13 Screw 14 Top plate 15 Convex Outlet 16 Plate-shaped shrapnel 17 Washer 18 Metal piece M333403
19 凹陷部 20 夹緊螺栓 21 螺孔 22 邊蓋 23 螺釘 24 腳架 25 底板 26 螺絲 27 固定螺母 28 基台 B1 長圓斗體 B2 橢圓斗體 B3 圓筒長圓斗體 B4 圓筒橢圓斗體 D1-D4 搬送方向 Μ 零件搬送道 N 零件搬送道 01 、02中心 R1 〜R6 半徑 X 圓弧部 XI 〜X6 圓弧壁 Υ 直線部 Y1 〜Y7 直線壁 Ζ 橢圓部 Z1 〜Z6 橢圓壁 1619 Depression 20 Clamping bolt 21 Screw hole 22 Side cover 23 Screw 24 Tripod 25 Base plate 26 Screw 27 Fixing nut 28 Base table B1 Round body B2 Elliptical body B3 Cylinder long round body B4 Cylinder oval body D1- D4 conveying direction 零件 Part conveying path N Part conveying path 01, 02 center R1 to R6 Radius X Arc part XI to X6 Arc wall 直线 Straight line Y1 to Y7 Straight wall 椭圆 Ellipse Z1 to Z6 Elliptical wall 16